DE10128587A1 - Control circuit with configuration input - Google Patents

Abstract

An electronic choke has a rectifier circuit connected to an AC voltage source. A smoothing circuit connected to the rectifier circuit's output and controlled by an intermediate circuit voltage regulator (1) generates an intermediate circuit voltage (Vz). A load circuit (8) wired to a lamp (LA) connects to the output of a DC/AC converter (7) fed by the intermediate circuit voltage.

Description

The present invention relates to a control circuit with a Configuration input for use in an electronic ballast.

Electronic ballasts for operating gas discharge lamps usually one or more control circuits for performing Control processes. Often these control circuits are as integrated circuits trained because in this way compact and faster working circuits can be realized. In the case of an electronic device disclosed in WO 99/34647 A1 Ballast is the control circuit for controlling the inverter for example in the form of an application-specific integrated circuit (Application Specific Integrated Circuit, ASIC) trained.

A disadvantage of integrated circuits, however, is that one Subsequent parameter changes or other influences are not easy can be carried out. While in circuits that are in purely analog form exist, there are many possibilities to intervene in the circuit afterwards certain parameters for adaptation to the lamp type used or the like change, the parameters for an integrated circuit are usually fixed.

To at least have some influence at a later date can, the ASIC described in WO 99/34647 A1 has one Configuration input, which is connected to a configuration resistor. The second connection of the configuration resistor is either grounded or a supply voltage potential is laid. The one falling over the resistance Voltage is then compared to an internal reference value, with the Controlling the inverter a first variant is selected if the above Configuration resistance falling voltage is greater than the reference potential, while the lamp is operated according to a second variant if the measured voltage is less than the reference value. In WO 99/34647 A1 in this way you can choose between a warm start or a cold start of the lamp become.

In this known solution, however, can only be added to the Circuit are intervened, since the control circuit can only determine whether the voltage drop across the configuration resistor greater or less than that Is the reference value. To make more extensive changes,  for example, a specific lamp type from a variety of options to select or set a time interval for the preheating time would be several such configuration inputs necessary, but this changes the design of the Circuit would complicate and this would take up a larger space. The advantages achieved by integrating the circuit would thereby be partially get lost again.

It is therefore an object of the present invention to provide a way to a control circuit to make subsequent parameter changes without a large number of configuration inputs would be necessary for this.

This object is achieved by a control circuit according to claim 1, which one Has configuration input with which the one connection of a Configuration resistor is connectable, the second connection to a first Reference potential is to be laid. According to the invention is a within the control circuit Power source provided with one connector on a second Reference potential lies and with its other connection with the configuration input is connectable. In addition, the control circuit contains an analog / digital Converter, which is also connected to the configuration input and one of the Resistance value of the configuration resistor corresponding digital value with generated at least 2 bits, and a configuration circuit with a memory, in where the digital value generated by the analog / digital converter is stored.

The main idea of the invention is therefore that, in contrast to the previously known solution is not just an either-or decision, but that the actual level of the resistance value as a configuration parameter is used. This increases the configuration resistance Information content assigned, being converted into a digital value, the then written to memory ensures that this information can be taken into account by the control circuit during a later operation. It should be noted that for the subsequent configuration of digital Circuits typically use logic configuration inputs.

Analog to the circuit known from WO 99/34647 A1, however, one can such a logical configuration input is only an either-or decision to be hit. Therefore, to make an extensive parameter setting would be a corresponding - relatively high - number of such logical Inputs necessary, which is avoided by the present invention.  

Developments of the invention are the subject of the dependent claims.

So is essential in the configuration of the control circuit according to the invention Meaning that it must be ensured that the decision on the choice of the Configuration resistance set configuration parameters also reliable and can be clearly recognized by the control circuit. For example, one incorrect detection of the one set via the configuration resistor Lamp type result in the lamp operating under the wrong operating conditions and may be damaged or even destroyed. Here is too take into account that the resistance values, the current sources and the reference potentials certain tolerances that lead to a falsification of the by the Analog / digital converter generated digital value can result. So therefore ensure that a configuration parameter set subsequently is reliably recognized, it is necessary to consider every possible configuration parameter assign a certain resistance range. Because of the limited Resolution can also be between a limited number in the present invention of configuration parameters can be selected.

However, to achieve the one that can be achieved with a single configuration input According to a further development, information content can be increased further be that the control circuit has a second current source, with its one Connection is at a further reference potential and with its other connection can also be connected to the configuration input. Joining the two Power sources with the configuration input take place via controllable switches, which are controlled by the configuration circuit in such a way that first the first Power source and then the second power source with the configuration input is connected. Externally, the configuration resistor can either be on the first or the second reference potential, so that not only the Resistance value of the configuration resistor but also its arrangement is taken into account. In an additional training it is then also possible to have two To use configuration resistors, the one to the first reference potential and the second is set to the second reference potential. Through a successively connecting the two power sources to the Configuration input can each separate the resistance values of the two Configuration resistances are determined and saved as configuration parameters become.

Saving the configuration parameters in digital form is particularly then an advantage if these digital values are implemented directly by the control circuit  can be. According to a development of the invention, the control circuit is therefore Part of an electronic ballast and detects one or more Operating parameters of the load circuit and / or a smoothing circuit for generation an intermediate circuit voltage and controls depending on the detected Operating parameters the inverter and / or a controllable switch Smoothing circuit on. The control circuit contains an analog / digital Converter that converts the recorded operating parameters into a minimum of 2 bits Implements digital value, the control circuit based on this digital value using a digital control circuit a switching information for operating the inverter and / or the controllable switch and calculated in the memory of the Configuration circuit stored configuration parameters taken into account. The In this development, the control circuit thus operates completely digitally, so that the configuration parameters subsequently set in a particularly simple manner can be taken into account.

The recorded operating parameters for the control loops can be, for example the DC link voltage, the lamp voltage or the lamp current.

The control circuit is preferably an application-specific integrated circuit educated. Furthermore, the control circuit preferably has only one Analogue / digital converter to implement the for the different Control processes recorded operating parameters and the configuration resistance in digital values work in time multiplex.

The invention will be explained below with reference to the accompanying drawing, the only FIG. 1 representing an electronic ballast for operating a gas discharge lamp, which contains the control circuit according to the invention.

However, before the control circuit according to the invention is explained in more detail, the general structure of the electronic ballast shown in FIG. 1 will first be described. The input of the ballast forms a network with the supply voltage U ₀ connected input filter 1, which has its output connected to a rectifier. 2 The rectified AC supply voltage is supplied to a smoothing circuit 3 , which in the present example is designed as a step-up converter and generates an intermediate circuit voltage U _Z across the storage capacitor C2 arranged on the output side. This intermediate circuit voltage U _Z is converted by an inverter 4 into a high-frequency AC voltage, which is fed to the load circuit with the gas discharge lamp LA connected to it.

The step-up converter is formed by a smoothing capacitor C1, an inductor L1, a diode D1 and a controllable switch S1 in the form of a MOS field-effect transistor. The inverter 4 consists of two MOS field effect transistors S2 and S3 arranged in a half-bridge arrangement. These three transistors S1-S3 are controlled by a driver circuit 7 , which in turn receives corresponding control information from a control circuit 6 , which calculates the control information on the basis of operating parameters of the smoothing circuit 3 and the load circuit 5 . For this purpose, the control circuit 6 via the input lines 11-13 operating parameters of the load circuit 5 - for example the lamp voltage and / or the lamp current - and the smoothing circuit 3 , in the present example the intermediate circuit voltage U _Z and the current I _L flowing through the inductor L1 - are specified more precisely , a parameter corresponding to this current I _L - transmitted.

The operating parameters detected via the three input lines 11-13 are converted into digital values with the aid of analog / digital converters ADC ₁ -ADC ₃ and fed to a digital control circuit 9 . The analog / digital converter ADC ₁ -ADC ₃ and the control circuit 9 are synchronized with the aid of a clock generator 8 , which transmits a corresponding clock signal to the individual components of the control circuit 6 . It should be noted that, contrary to the schematic representation in FIG. 1, the control circuit 6 in practice preferably has only a single analog / digital converter which is operated in time division multiplex and converts the operating parameters supplied via the input lines 11-13 one after the other into the corresponding digital values ,

This digital configuration enables the control circuit 6 to be kept extremely compact in its dimensions. In addition, optimal and fast control properties can be achieved. Furthermore, the electronic ballast is able to operate different lamp types. However, in order to be able to display the corresponding lamp type before the control circuit 6 is operated , a subsequent configuration parameter change must be ensured.

For this purpose, the configuration input 17 is provided, the function of which will be explained below. Internally, the configuration _input 17 can be connected to two current sources I _q1 and I _q2, which are connected on the one hand to an internal supply voltage _potential V _dd and on the other hand to ground. The two current sources I _q1 and I _{q2 are} connected to the configuration _input 17 via two switches S4 and S5, which are controlled by a configuration _circuit 10 provided in the control circuit 6 .

Externally, the configuration _input 17 can be connected to two configuration _resistors R _q1 and R _q2 , the remaining connections of which are connected, on the one hand, to ground and, on the other hand, to the supply voltage _potential V _dd also provided by the control circuit 6 .

To carry out the configuration, the configuration circuit 10 switches the two switches S4 and S5, for example in such a way that the current source I _{q1 is first} connected to the configuration input 17 while the switch S5 remains open. In this case, a voltage drops across the first configuration resistor R _q1 , the magnitude of which depends on the resistance value. This voltage is detected by the analog / digital converter ADC ₄ and converted into a digital value with an accuracy of at least 2 bits. The conversion into the digital value is carried out according to a predetermined tolerance scheme, which takes into account that larger deviations can occur with higher resistance values and thus voltage values. As a result, the voltage levels corresponding to an increase in the digital value increase. In this way, taking into account the tolerances with a configuration resistor, an information depth of 4 bits can be obtained, whereby an error detection is excluded.

The digital value generated in this way is stored by the configuration circuit 10 , which in a further step _controls the switches S4 and S5 such that the second current source I _{q2 is now} connected to the configuration _input 17 while the switch S4 is open. In this case, the current generated by the second current source now passes through the second Konfigurierungswiderstand R _q2, wherein again detects the voltage applied to the configuration input 17 voltage value of the analog / digital converter ADC ₄ and converted into a corresponding digital information. This second digital value is also stored in the configuration circuit 10 .

The voltage values present at the configuration input 17 are in turn preferably implemented by a single analog / digital converter contained in the control circuit 6 , which is used to convert all the signals present at the inputs of the control circuit 6 and accordingly operates in time-division multiplex.

The information transmitted by the two configuration _resistors R _q1 and R _q2 is then made available to the control circuit 9 at a later point in time, so that the latter can take into account the configuration _parameters subsequently set when operating the lamp. For example, the desired lamp type can be set subsequently. Of course, the sequence for activating the two switches S4 and S5 can also be interchanged.

As an alternative to the variant shown in FIG. 1, there is also the possibility of using only a single configuration resistor and connecting it either to the supply voltage potential V _dd or to ground. Although this means that less information can be transmitted, in comparison to the variant with two configuration resistors shown in FIG. 1, it is avoided that current flows permanently through both resistors. In addition, the choice of the arrangement of the single configuration resistor can be used as additional information.

Compared to the previously known solution, the present invention thus offers the Possibility of using only a single configuration input subsequently make extensive configuration parameter changes. The digital design of the entire control circuit can also do that Ballast can be kept extremely compact in size, being a Another advantage of digital design is that it is better and more flexible Control properties can be achieved. The one according to the invention is preferred Control circuit as an application-specific integrated circuit (Application Specific Integrated Circuit, ASIC).

Claims (13)

1. control circuit ( 6 ), in particular for use in an electrical ballast for operating at least one gas discharge lamp (LA),
with a configuration input ( 17 ), to which one connection of a configuration resistor (R _q1 ) can be connected, the other connection of which has to be connected to a first reference potential,
marked by
at least one current source (I _q1 ), the one connection of which is at a second reference potential (V _dd ) and the other connection of which is connectable to the configuration input ( 17 ),
an analog / digital converter (ADC ₄ ), which is connected to the configuration input ( 17 ) and generates a digital value corresponding to the resistance value of the configuration resistor (R _g1 ) with at least 2 bits, and
a configuration circuit ( 10 ) which contains at least one memory in which the digital value is stored. 2. Control circuit according to claim 1, characterized in that the current source (I _q1 ) via a controllable switch (S4) with the configuration input ( 17 ) can be connected, this switch (S4) being controlled by the configuration circuit ( 10 ). 3. _{Control circuit} according to claim 2, characterized in that it has a further current source (I _q2 ), which is connected to the first reference potential with its one connection and with its other connection via a second controllable switch (S5) to the configuration input ( 17th ) is connectable, the configuration resistor (R _q1 ) having its second connection to be connected to the first or the second reference potential and the two switches (S4, S5) being controlled by the configuration circuit ( 10 ) such that initially only one of the two Switch (S4, S5) and then only the other is closed. 4. _{Control circuit} according to claim 3, characterized in that with the configuration _input ( 17 ) two configuration _resistors (R _q1 , R _q2 ) can be connected, the connections of which are not connected to the configuration _input ( 17 ) on the one hand on the first and on the other hand on the second Reference potential must be set, the configuration _circuit ( 10 ) _storing two digital _values corresponding to the resistance _{values of} the two configuration resistors (R _q1 , R _q2 ) with at least 2 bits in the memory. 5. Electronic ballast for at least one gas discharge lamp (LA), with
a connectable to an AC voltage source (U ₀₎ the rectifier circuit (2), a load connected to the output of the rectifier circuit (2) smoothing circuit (3) for generating an intermediate circuit voltage (U _Z) and fed with the intermediate circuit voltage (U _Z) inverter (4) , at the output of which a connection for the lamp (LA) containing load circuit ( 5 ) is connected,
The ballast has a control circuit ( 6 ) which detects one or more operating parameters of the load circuit ( 5 ) and / or the smoothing circuit ( 3 ) and, depending on the at least one operating parameter, the inverter ( 4 ) and / or a controllable switch (S1 ) drives the smoothing circuit,
characterized,
that the control circuit ( 6 ) has an analog / digital converter (ADC _1-4 ) for converting the detected operating parameter into a digital value consisting of at least 2 bits, the control circuit ( 6 ) based on this digital value in a digital control circuit ( 9 ) calculates switching information for operating the inverter ( 4 ) and / or the controllable switch (S1) of the switching regulator and transmits it to a driver circuit ( 7 ) which converts this switching information into a corresponding control signal,
and that the control circuit is designed according to one of claims 1 to 4 and takes into account the at least one value stored in the memory of the configuration circuit ( 10 ) when calculating the switching information. 6. Electronic ballast according to claim 5, characterized in that the smoothing circuit ( 3 ) is formed by a step-up converter. 7. Electronic ballast according to claim 6, characterized in that the control circuit ( 6 ) controls a controllable switch (S1) of the step-up converter. 8. Electronic ballast according to claim 7, characterized in that the control circuit ( 6 ) detects the intermediate circuit voltage (U _Z ). 9. Electronic ballast according to claim 7 or 8, characterized in that the control circuit ( 6 ) detects the current (I _L ) flowing through an inductance (L) of the step-up converter. 10. Electronic ballast according to one of claims 5 to 9, characterized in that the control circuit ( 6 ) detects the lamp voltage. 11. Electronic ballast according to one of claims 5 or 10, characterized in that the control circuit ( 6 ) detects the lamp current. 12. Electronic ballast according to one of claims 5 or 11, characterized in that the control unit ( 6 ) has a clock generator ( 8 ) for transmitting a clock signal to the components (ADC ₁ -ADC ₄ , 9 , 10 ) of the control unit ( 6 ) , 13. Electronic ballast according to one of the preceding claims, characterized in that the control unit ( 6 ) is designed as an application-specific integrated circuit.